Innovenergy_trunk/firmware/opt/dbus-fz-sonick-48tl-with-s3/old_signals.py

548 lines
26 KiB
Python
Executable File

# coding=utf-8
import config as cfg
from convert import mean, read_float, read_led_state, read_bool, count_bits, comma_separated, read_bitmap, return_in_list, first, read_hex_string
from data import BatterySignal, Battery, LedColor, ServiceSignal, BatteryStatus, LedState, CsvSignal
# noinspection PyUnreachableCode
if False:
from typing import List, Iterable
def init_service_signals(batteries):
print("INSIDE INIT SERVICE SIGNALS")
# type: (List[Battery]) -> Iterable[ServiceSignal]
n_batteries = len(batteries)
product_name = cfg.PRODUCT_NAME + ' x' + str(n_batteries)
return [
ServiceSignal('/NbOfBatteries', n_batteries), # TODO: nb of operational batteries
ServiceSignal('/Mgmt/ProcessName', __file__),
ServiceSignal('/Mgmt/ProcessVersion', cfg.SOFTWARE_VERSION),
ServiceSignal('/Mgmt/Connection', cfg.CONNECTION),
ServiceSignal('/DeviceInstance', cfg.DEVICE_INSTANCE),
ServiceSignal('/ProductName', product_name),
ServiceSignal('/ProductId', cfg.PRODUCT_ID),
ServiceSignal('/Connected', 1)
]
def init_battery_signals():
# type: () -> Iterable[BatterySignal]
print("START INIT SIGNALS")
read_voltage = read_float(register=999, scale_factor=0.01, offset=0)
read_current = read_float(register=1000, scale_factor=0.01, offset=-10000)
read_led_amber = read_led_state(register=1004, led=LedColor.amber)
read_led_green = read_led_state(register=1004, led=LedColor.green)
read_led_blue = read_led_state(register=1004, led=LedColor.blue)
read_led_red = read_led_state(register=1004, led=LedColor.red)
def read_power(status):
# type: (BatteryStatus) -> int
return int(read_current(status) * read_voltage(status))
def calc_power_limit_imposed_by_voltage_limit(v, i, v_limit, r_int):
# type: (float, float, float, float) -> float
dv = v_limit - v
di = dv / r_int
p_limit = v_limit * (i + di)
return p_limit
def calc_power_limit_imposed_by_current_limit(v, i, i_limit, r_int):
# type: (float, float, float, float) -> float
di = i_limit - i
dv = di * r_int
p_limit = i_limit * (v + dv)
return p_limit
def calc_max_charge_power(status):
# type: (BatteryStatus) -> int
n_strings = number_of_active_strings(status)
i_max = n_strings * cfg.I_MAX_PER_STRING
v_max = cfg.V_MAX
r_int_min = cfg.R_STRING_MIN / n_strings
r_int_max = cfg.R_STRING_MAX / n_strings
v = read_voltage(status)
i = read_current(status)
p_limits = [
calc_power_limit_imposed_by_voltage_limit(v, i, v_max, r_int_min),
calc_power_limit_imposed_by_voltage_limit(v, i, v_max, r_int_max),
calc_power_limit_imposed_by_current_limit(v, i, i_max, r_int_min),
calc_power_limit_imposed_by_current_limit(v, i, i_max, r_int_max),
]
p_limit = min(p_limits) # p_limit is normally positive here (signed)
p_limit = max(p_limit, 0) # charge power must not become negative
return int(p_limit)
def calc_max_discharge_power(status):
n_strings = number_of_active_strings(status)
max_discharge_current = n_strings*cfg.I_MAX_PER_STRING
return int(max_discharge_current*read_voltage(status))
def read_battery_cold(status):
return \
read_led_green(status) >= LedState.blinking_slow and \
read_led_blue(status) >= LedState.blinking_slow
def read_soc(status):
soc = read_float(register=1053, scale_factor=0.1, offset=0)(status)
# if the SOC is 100 but EOC is not yet reached, report 99.9 instead of 100
if soc > 99.9 and not read_eoc_reached(status):
return 99.9
if soc >= 99.9 and read_eoc_reached(status):
return 100
return soc
def hex_string_to_ascii(hex_string):
# Ensure the hex_string is correctly formatted without spaces
hex_string = hex_string.replace(" ", "")
# Convert every two characters (a byte) in the hex string to ASCII
ascii_string = ''.join([chr(int(hex_string[i:i+2], 16)) for i in range(0, len(hex_string), 2)])
return ascii_string
battery_status_reader = read_hex_string(1060,2)
def read_eoc_reached(status):
battery_status_string = battery_status_reader(status)
return hex_string_to_ascii(battery_status_string) == "EOC_"
read_limb_bitmap = read_bitmap(1059)
def interpret_limb_bitmap(bitmap_value):
#print("DIABASE TIN TIMI KAI MPIKE STIN INTERPRET LIMB BITMAP")
# The bit for string 1 also monitors all 5 strings: 0000 0000 means All 5 strings activated. 0000 0001 means string 1 disabled.
string1_disabled = int((bitmap_value & 0b00001) != 0)
string2_disabled = int((bitmap_value & 0b00010) != 0)
string3_disabled = int((bitmap_value & 0b00100) != 0)
string4_disabled = int((bitmap_value & 0b01000) != 0)
string5_disabled = int((bitmap_value & 0b10000) != 0)
n_limb_strings = string1_disabled+string2_disabled+string3_disabled+string4_disabled+string5_disabled
#print("KAI I TIMI EINAI: ", n_limb_strings)
return n_limb_strings
def limp_strings_value(status):
return interpret_limb_bitmap(read_limb_bitmap(status))
def number_of_active_strings(status):
return cfg.NUM_OF_STRINGS_PER_BATTERY - limp_strings_value(status)
def max_discharge_current(status):
#print("AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAinside discharge current")
#exit(0)
return number_of_active_strings(status) * cfg.I_MAX_PER_STRING
def max_charge_current(status):
return status.battery.ampere_hours/2
def read_switch_closed(status):
value = read_bool(base_register=1013, bit=0)(status)
if value:
return False
return True
def read_alarm_out_active(status):
value = read_bool(base_register=1013, bit=1)(status)
if value:
return False
return True
def read_aux_relay(status):
value = read_bool(base_register=1013, bit=4)(status)
if value:
return False
return True
return [
BatterySignal('/TimeToTOCRequest', max, read_float(register=1052)),
BatterySignal('/EOCReached', return_in_list, read_eoc_reached),
BatterySignal('/NumOfLimbStrings', return_in_list, limp_strings_value),
BatterySignal('/Dc/0/Voltage', mean, get_value=read_voltage, unit='V'),
BatterySignal('/Dc/0/Current', sum, get_value=read_current, unit='A'),
BatterySignal('/Dc/0/Power', sum, get_value=read_power, unit='W'),
BatterySignal('/BussVoltage', mean, read_float(register=1001, scale_factor=0.01, offset=0), unit='V'),
BatterySignal('/Soc', mean, read_soc, unit='%'),
BatterySignal('/LowestSoc', min, read_float(register=1053, scale_factor=0.1, offset=0), unit='%'),
BatterySignal('/Dc/0/Temperature', mean, read_float(register=1003, scale_factor=0.1, offset=-400), unit='C'),
BatterySignal('/Dc/0/LowestTemperature', min, read_float(register=1003, scale_factor=0.1, offset=-400), unit='C'),
#BatterySignal('/NumberOfWarningFlags', sum, count_bits(base_register=1005, nb_of_registers=3, nb_of_bits=47)),
BatterySignal('/WarningFlags/TaM1', return_in_list, read_bool(base_register=1005, bit=1)),
BatterySignal('/WarningFlags/TbM1', return_in_list, read_bool(base_register=1005, bit=4)),
BatterySignal('/WarningFlags/VBm1', return_in_list, read_bool(base_register=1005, bit=6)),
BatterySignal('/WarningFlags/VBM1', return_in_list, read_bool(base_register=1005, bit=8)),
BatterySignal('/WarningFlags/IDM1', return_in_list, read_bool(base_register=1005, bit=10)),
BatterySignal('/WarningFlags/vsm1', return_in_list, read_bool(base_register=1005, bit=22)),
BatterySignal('/WarningFlags/vsM1', return_in_list, read_bool(base_register=1005, bit=24)),
BatterySignal('/WarningFlags/iCM1', return_in_list, read_bool(base_register=1005, bit=26)),
BatterySignal('/WarningFlags/iDM1', return_in_list, read_bool(base_register=1005, bit=28)),
BatterySignal('/WarningFlags/MID1', return_in_list, read_bool(base_register=1005, bit=30)),
BatterySignal('/WarningFlags/BLPW', return_in_list, read_bool(base_register=1005, bit=32)),
BatterySignal('/WarningFlags/CCBF', return_in_list, read_bool(base_register=1005, bit=33)),
BatterySignal('/WarningFlags/Ah_W', return_in_list, read_bool(base_register=1005, bit=35)),
BatterySignal('/WarningFlags/MPMM', return_in_list, read_bool(base_register=1005, bit=38)),
#BatterySignal('/WarningFlags/TCMM', any, read_bool(base_register=1005, bit=39)),
BatterySignal('/WarningFlags/TCdi', return_in_list, read_bool(base_register=1005, bit=40)),
#BatterySignal('/WarningFlags/WMTO', any, read_bool(base_register=1005, bit=41)),
BatterySignal('/WarningFlags/LMPW', return_in_list, read_bool(base_register=1005, bit=44)),
#BatterySignal('/WarningFlags/CELL1', any, read_bool(base_register=1005, bit=46)),
BatterySignal('/WarningFlags/TOCW', return_in_list, read_bool(base_register=1005, bit=47)),
BatterySignal('/WarningFlags/BUSL', return_in_list, read_bool(base_register=1005, bit=49)),
#BatterySignal('/NumberOfAlarmFlags', sum, count_bits(base_register=1009, nb_of_registers=3, nb_of_bits=47)),
BatterySignal('/AlarmFlags/Tam', return_in_list, read_bool(base_register=1005, bit=0)),
BatterySignal('/AlarmFlags/TaM2', return_in_list, read_bool(base_register=1005, bit=2)),
BatterySignal('/AlarmFlags/Tbm', return_in_list, read_bool(base_register=1005, bit=3)),
BatterySignal('/AlarmFlags/TbM2', return_in_list, read_bool(base_register=1005, bit=5)),
BatterySignal('/AlarmFlags/VBm2', return_in_list, read_bool(base_register=1005, bit=7)),
BatterySignal('/AlarmFlags/VBM2', return_in_list, read_bool(base_register=1005, bit=9)),
BatterySignal('/AlarmFlags/IDM2', return_in_list, read_bool(base_register=1005, bit=11)),
BatterySignal('/AlarmFlags/ISOB', return_in_list, read_bool(base_register=1005, bit=12)),
BatterySignal('/AlarmFlags/MSWE', return_in_list, read_bool(base_register=1005, bit=13)),
BatterySignal('/AlarmFlags/FUSE', return_in_list, read_bool(base_register=1005, bit=14)),
BatterySignal('/AlarmFlags/HTRE', return_in_list, read_bool(base_register=1005, bit=15)),
BatterySignal('/AlarmFlags/TCPE', return_in_list, read_bool(base_register=1005, bit=16)),
BatterySignal('/AlarmFlags/STRE', return_in_list, read_bool(base_register=1005, bit=17)),
BatterySignal('/AlarmFlags/CME', return_in_list, read_bool(base_register=1005, bit=18)),
BatterySignal('/AlarmFlags/HWFL', return_in_list, read_bool(base_register=1005, bit=19)),
BatterySignal('/AlarmFlags/HWEM', return_in_list, read_bool(base_register=1005, bit=20)),
BatterySignal('/AlarmFlags/ThM', return_in_list, read_bool(base_register=1005, bit=21)),
#BatterySignal('/AlarmFlags/vsm1', any, read_bool(base_register=1005, bit=22)),
BatterySignal('/AlarmFlags/vsm2', return_in_list, read_bool(base_register=1005, bit=23)),
BatterySignal('/AlarmFlags/vsM2', return_in_list, read_bool(base_register=1005, bit=25)),
BatterySignal('/AlarmFlags/iCM2', return_in_list, read_bool(base_register=1005, bit=27)),
BatterySignal('/AlarmFlags/iDM2', return_in_list, read_bool(base_register=1005, bit=29)),
BatterySignal('/AlarmFlags/MID2', return_in_list, read_bool(base_register=1005, bit=31)),
#BatterySignal('/AlarmFlags/CCBF', any, read_bool(base_register=1005, bit=33)),
#BatterySignal('/AlarmFlags/AhFL', any, read_bool(base_register=1005, bit=34)),
#BatterySignal('/AlarmFlags/TbCM', any, read_bool(base_register=1005, bit=36)),
#BatterySignal('/AlarmFlags/BRNF', any, read_bool(base_register=1005, bit=37)),
BatterySignal('/AlarmFlags/HTFS', return_in_list, read_bool(base_register=1005, bit=42)),
BatterySignal('/AlarmFlags/DATA', return_in_list, read_bool(base_register=1005, bit=43)),
BatterySignal('/AlarmFlags/LMPA', return_in_list, read_bool(base_register=1005, bit=45)),
BatterySignal('/AlarmFlags/HEBT', return_in_list, read_bool(base_register=1005, bit=46)),
#BatterySignal('/AlarmFlags/bit47AlarmDummy', any,read_bool(base_register=1005, bit=47)),
BatterySignal('/AlarmFlags/CURM', return_in_list, read_bool(base_register=1005, bit=48)),
BatterySignal('/Diagnostics/LedStatus/Red', first, read_led_red),
BatterySignal('/Diagnostics/LedStatus/Blue', first, read_led_blue),
BatterySignal('/Diagnostics/LedStatus/Green', first, read_led_green),
BatterySignal('/Diagnostics/LedStatus/Amber', first, read_led_amber),
BatterySignal('/Diagnostics/IoStatus/MainSwitchClosed', return_in_list, read_switch_closed),
BatterySignal('/Diagnostics/IoStatus/AlarmOutActive', return_in_list, read_alarm_out_active),
BatterySignal('/Diagnostics/IoStatus/InternalFanActive', return_in_list, read_bool(base_register=1013, bit=2)),
BatterySignal('/Diagnostics/IoStatus/VoltMeasurementAllowed', return_in_list, read_bool(base_register=1013, bit=3)),
BatterySignal('/Diagnostics/IoStatus/AuxRelay', return_in_list, read_aux_relay),
BatterySignal('/Diagnostics/IoStatus/RemoteState', return_in_list, read_bool(base_register=1013, bit=5)),
BatterySignal('/Diagnostics/IoStatus/RiscOn', return_in_list, read_bool(base_register=1013, bit=6)),
BatterySignal('/IoStatus/BatteryCold', any, read_battery_cold),
# see protocol doc page 7
BatterySignal('/Info/MaxDischargeCurrent', sum, max_discharge_current, unit='A'),
BatterySignal('/Info/MaxChargeCurrent', sum, max_charge_current, unit='A'),
BatterySignal('/Info/MaxChargeVoltage', min, lambda bs: bs.battery.v_max, unit='V'),
BatterySignal('/Info/MinDischargeVoltage', max, lambda bs: bs.battery.v_min, unit='V'),
BatterySignal('/Info/BatteryLowVoltage' , max, lambda bs: bs.battery.v_min-2, unit='V'),
BatterySignal('/Info/NumberOfStrings', sum, number_of_active_strings),
BatterySignal('/Info/MaxChargePower', sum, calc_max_charge_power),
BatterySignal('/Info/MaxDischargePower', sum, calc_max_discharge_power),
BatterySignal('/FirmwareVersion', comma_separated, lambda bs: bs.battery.firmware_version),
BatterySignal('/HardwareVersion', comma_separated, lambda bs: bs.battery.hardware_version),
BatterySignal('/BmsVersion', comma_separated, lambda bs: bs.battery.bms_version)
]
def create_csv_signals(firmware_version):
read_voltage = read_float(register=999, scale_factor=0.01, offset=0)
read_current = read_float(register=1000, scale_factor=0.01, offset=-10000)
read_limb_bitmap = read_bitmap(1059)
def read_power(status):
return int(read_current(status) * read_voltage(status))
def string1_disabled(status):
bitmap_value = read_limb_bitmap(status)
return int((bitmap_value & 0b00001) != 0)
def string2_disabled(status):
bitmap_value = read_limb_bitmap(status)
return int((bitmap_value & 0b00010) != 0)
def string3_disabled(status):
bitmap_value = read_limb_bitmap(status)
return int((bitmap_value & 0b00100) != 0)
def string4_disabled(status):
bitmap_value = read_limb_bitmap(status)
return int((bitmap_value & 0b01000) != 0)
def string5_disabled(status):
bitmap_value = read_limb_bitmap(status)
return int((bitmap_value & 0b10000) != 0)
read_limb_bitmap = read_bitmap(1059)
def interpret_limb_bitmap(bitmap_value):
#print("DIABASE TIN TIMI KAI MPIKE STIN INTERPRET LIMB BITMAP")
# The bit for string 1 also monitors all 5 strings: 0000 0000 means All 5 strings activated. 0000 0001 means string 1 disabled.
string1_disabled = int((bitmap_value & 0b00001) != 0)
string2_disabled = int((bitmap_value & 0b00010) != 0)
string3_disabled = int((bitmap_value & 0b00100) != 0)
string4_disabled = int((bitmap_value & 0b01000) != 0)
string5_disabled = int((bitmap_value & 0b10000) != 0)
n_limb_strings = string1_disabled+string2_disabled+string3_disabled+string4_disabled+string5_disabled
#print("KAI I TIMI EINAI: ", n_limb_strings)
return n_limb_strings
def limp_strings_value(status):
return interpret_limb_bitmap(read_limb_bitmap(status))
def calc_max_charge_power(status):
# type: (BatteryStatus) -> int
n_strings = cfg.NUM_OF_STRINGS_PER_BATTERY-limp_strings_value(status)
i_max = n_strings * cfg.I_MAX_PER_STRING
v_max = cfg.V_MAX
r_int_min = cfg.R_STRING_MIN / n_strings
r_int_max = cfg.R_STRING_MAX / n_strings
v = read_voltage(status)
i = read_current(status)
p_limits = [
calc_power_limit_imposed_by_voltage_limit(v, i, v_max, r_int_min),
calc_power_limit_imposed_by_voltage_limit(v, i, v_max, r_int_max),
calc_power_limit_imposed_by_current_limit(v, i, i_max, r_int_min),
calc_power_limit_imposed_by_current_limit(v, i, i_max, r_int_max),
]
p_limit = min(p_limits) # p_limit is normally positive here (signed)
p_limit = max(p_limit, 0) # charge power must not become negative
return int(p_limit)
def calc_max_discharge_power(status):
n_strings = cfg.NUM_OF_STRINGS_PER_BATTERY-limp_strings_value(status)
max_discharge_current = n_strings*cfg.I_MAX_PER_STRING
return int(max_discharge_current*read_voltage(status))
total_current = read_float(register=1062, scale_factor=0.01, offset=-10000)
def read_total_current(status):
return total_current(status)
def read_heating_current(status):
return total_current(status) - read_current(status)
def read_heating_power(status):
return read_voltage(status) * read_heating_current(status)
soc_ah = read_float(register=1002, scale_factor=0.1, offset=-10000)
def read_soc_ah(status):
return soc_ah(status)
def return_led_state(status, color):
led_state = read_led_state(register=1004, led=color)(status)
if led_state == LedState.blinking_fast or led_state == LedState.blinking_slow:
return "Blinking"
elif led_state == LedState.on:
return "On"
elif led_state == LedState.off:
return "Off"
return "Unknown"
def return_led_state_blue(status):
return return_led_state(status, LedColor.blue)
def return_led_state_red(status):
return return_led_state(status, LedColor.red)
def return_led_state_green(status):
return return_led_state(status, LedColor.green)
def return_led_state_amber(status):
return return_led_state(status, LedColor.amber)
def read_switch_closed(status):
value = read_bool(base_register=1013, bit=0)(status)
if value:
return False
return True
def read_alarm_out_active(status):
value = read_bool(base_register=1013, bit=1)(status)
if value:
return False
return True
def read_aux_relay(status):
value = read_bool(base_register=1013, bit=4)(status)
if value:
return False
return True
battery_status_reader = read_hex_string(1060,2)
def hex_string_to_ascii(hex_string):
# Ensure the hex_string is correctly formatted without spaces
hex_string = hex_string.replace(" ", "")
# Convert every two characters (a byte) in the hex string to ASCII
ascii_string = ''.join([chr(int(hex_string[i:i+2], 16)) for i in range(0, len(hex_string), 2)])
return ascii_string
def read_eoc_reached(status):
battery_status_string = battery_status_reader(status)
return hex_string_to_ascii(battery_status_string) == "EOC_"
def read_serial_number(status):
serial_regs = [1055, 1056, 1057, 1058]
serial_parts = []
for reg in serial_regs:
# reading each register as a single hex value
hex_value_fun = read_hex_string(reg, 1)
hex_value = hex_value_fun(status)
# append without spaces and leading zeros stripped if any
serial_parts.append(hex_value.replace(' ', ''))
# concatenate all parts to form the full serial number
serial_number = ''.join(serial_parts).rstrip('0')
return serial_number
def time_since_toc_in_time_format(status):
time_in_minutes = read_float(register=1052)(status)
# Convert minutes to total seconds
total_seconds = int(time_in_minutes * 60)
# Calculate days, hours, minutes, and seconds
days = total_seconds // (24 * 3600)
total_seconds = total_seconds % (24 * 3600)
hours = total_seconds // 3600
total_seconds %= 3600
minutes = total_seconds // 60
seconds = total_seconds % 60
# Format the string to show days.hours:minutes:seconds
return "{}.{:02}:{:02}:{:02}".format(days, hours, minutes, seconds)
def calc_power_limit_imposed_by_voltage_limit(v, i, v_limit, r_int):
# type: (float, float, float, float) -> float
dv = v_limit - v
di = dv / r_int
p_limit = v_limit * (i + di)
return p_limit
def calc_power_limit_imposed_by_current_limit(v, i, i_limit, r_int):
# type: (float, float, float, float) -> float
di = i_limit - i
dv = di * r_int
p_limit = i_limit * (v + dv)
return p_limit
return [
CsvSignal('/Battery/Devices/FwVersion', firmware_version),
CsvSignal('/Battery/Devices/Dc/Power', read_power, 'W'),
CsvSignal('/Battery/Devices/Dc/Voltage', read_voltage, 'V'),
CsvSignal('/Battery/Devices/Soc', read_float(register=1053, scale_factor=0.1, offset=0), '%'),
CsvSignal('/Battery/Devices/Temperatures/Cells/Average', read_float(register=1003, scale_factor=0.1, offset=-400), 'C'),
CsvSignal('/Battery/Devices/Dc/Current', read_current, 'A'),
CsvSignal('/Battery/Devices/BusCurrent', read_total_current, 'A'),
CsvSignal('/Battery/Devices/CellsCurrent', read_current, 'A'),
CsvSignal('/Battery/Devices/HeatingCurrent', read_heating_current, 'A'),
CsvSignal('/Battery/Devices/HeatingPower', read_heating_power, 'W'),
CsvSignal('/Battery/Devices/SOCAh', read_soc_ah),
CsvSignal('/Battery/Devices/Leds/Blue', return_led_state_blue),
CsvSignal('/Battery/Devices/Leds/Red', return_led_state_red),
CsvSignal('/Battery/Devices/Leds/Green', return_led_state_green),
CsvSignal('/Battery/Devices/Leds/Amber', return_led_state_amber),
CsvSignal('/Battery/Devices/BatteryStrings/String1Active', string1_disabled),
CsvSignal('/Battery/Devices/BatteryStrings/String2Active', string2_disabled),
CsvSignal('/Battery/Devices/BatteryStrings/String3Active', string3_disabled),
CsvSignal('/Battery/Devices/BatteryStrings/String4Active', string4_disabled),
CsvSignal('/Battery/Devices/BatteryStrings/String5Active', string5_disabled),
CsvSignal('/Battery/Devices/IoStatus/ConnectedToDcBus', read_switch_closed),
CsvSignal('/Battery/Devices/IoStatus/AlarmOutActive', read_alarm_out_active),
CsvSignal('/Battery/Devices/IoStatus/InternalFanActive', read_bool(base_register=1013, bit=2)),
CsvSignal('/Battery/Devices/IoStatus/VoltMeasurementAllowed', read_bool(base_register=1013, bit=3)),
CsvSignal('/Battery/Devices/IoStatus/AuxRelayBus', read_aux_relay),
CsvSignal('/Battery/Devices/IoStatus/RemoteStateActive', read_bool(base_register=1013, bit=5)),
CsvSignal('/Battery/Devices/IoStatus/RiscActive', read_bool(base_register=1013, bit=6)),
CsvSignal('/Battery/Devices/Eoc', read_eoc_reached),
CsvSignal('/Battery/Devices/SerialNumber', read_serial_number),
CsvSignal('/Battery/Devices/TimeSinceTOC', time_since_toc_in_time_format),
CsvSignal('/Battery/Devices/MaxChargePower', calc_max_charge_power),
CsvSignal('/Battery/Devices/MaxDischargePower', calc_max_discharge_power),
]
def read_warning_and_alarm_flags():
return [
# Warnings
CsvSignal('/Battery/Devices/WarningFlags/TaM1', read_bool(base_register=1005, bit=1)),
CsvSignal('/Battery/Devices/WarningFlags/TbM1', read_bool(base_register=1005, bit=4)),
CsvSignal('/Battery/Devices/WarningFlags/VBm1', read_bool(base_register=1005, bit=6)),
CsvSignal('/Battery/Devices/WarningFlags/VBM1', read_bool(base_register=1005, bit=8)),
CsvSignal('/Battery/Devices/WarningFlags/IDM1', read_bool(base_register=1005, bit=10)),
CsvSignal('/Battery/Devices/WarningFlags/vsm1', read_bool(base_register=1005, bit=22)),
CsvSignal('/Battery/Devices/WarningFlags/vsM1', read_bool(base_register=1005, bit=24)),
CsvSignal('/Battery/Devices/WarningFlags/iCM1', read_bool(base_register=1005, bit=26)),
CsvSignal('/Battery/Devices/WarningFlags/iDM1', read_bool(base_register=1005, bit=28)),
CsvSignal('/Battery/Devices/WarningFlags/MID1', read_bool(base_register=1005, bit=30)),
CsvSignal('/Battery/Devices/WarningFlags/BLPW', read_bool(base_register=1005, bit=32)),
CsvSignal('/Battery/Devices/WarningFlags/CCBF', read_bool(base_register=1005, bit=33)),
CsvSignal('/Battery/Devices/WarningFlags/Ah_W', read_bool(base_register=1005, bit=35)),
CsvSignal('/Battery/Devices/WarningFlags/MPMM', read_bool(base_register=1005, bit=38)),
CsvSignal('/Battery/Devices/WarningFlags/TCdi', read_bool(base_register=1005, bit=40)),
CsvSignal('/Battery/Devices/WarningFlags/LMPW', read_bool(base_register=1005, bit=44)),
CsvSignal('/Battery/Devices/WarningFlags/TOCW', read_bool(base_register=1005, bit=47)),
CsvSignal('/Battery/Devices/WarningFlags/BUSL', read_bool(base_register=1005, bit=49)),
], [
# Alarms
CsvSignal('/Battery/Devices/AlarmFlags/Tam', read_bool(base_register=1005, bit=0)),
CsvSignal('/Battery/Devices/AlarmFlags/TaM2', read_bool(base_register=1005, bit=2)),
CsvSignal('/Battery/Devices/AlarmFlags/Tbm', read_bool(base_register=1005, bit=3)),
CsvSignal('/Battery/Devices/AlarmFlags/TbM2', read_bool(base_register=1005, bit=5)),
CsvSignal('/Battery/Devices/AlarmFlags/VBm2', read_bool(base_register=1005, bit=7)),
CsvSignal('/Battery/Devices/AlarmFlags/VBM2', read_bool(base_register=1005, bit=9)),
CsvSignal('/Battery/Devices/AlarmFlags/IDM2', read_bool(base_register=1005, bit=11)),
CsvSignal('/Battery/Devices/AlarmFlags/ISOB', read_bool(base_register=1005, bit=12)),
CsvSignal('/Battery/Devices/AlarmFlags/MSWE', read_bool(base_register=1005, bit=13)),
CsvSignal('/Battery/Devices/AlarmFlags/FUSE', read_bool(base_register=1005, bit=14)),
CsvSignal('/Battery/Devices/AlarmFlags/HTRE', read_bool(base_register=1005, bit=15)),
CsvSignal('/Battery/Devices/AlarmFlags/TCPE', read_bool(base_register=1005, bit=16)),
CsvSignal('/Battery/Devices/AlarmFlags/STRE', read_bool(base_register=1005, bit=17)),
CsvSignal('/Battery/Devices/AlarmFlags/CME', read_bool(base_register=1005, bit=18)),
CsvSignal('/Battery/Devices/AlarmFlags/HWFL', read_bool(base_register=1005, bit=19)),
CsvSignal('/Battery/Devices/AlarmFlags/HWEM', read_bool(base_register=1005, bit=20)),
CsvSignal('/Battery/Devices/AlarmFlags/ThM', read_bool(base_register=1005, bit=21)),
CsvSignal('/Battery/Devices/AlarmFlags/vsm2', read_bool(base_register=1005, bit=23)),
CsvSignal('/Battery/Devices/AlarmFlags/vsM2', read_bool(base_register=1005, bit=25)),
CsvSignal('/Battery/Devices/AlarmFlags/iCM2', read_bool(base_register=1005, bit=27)),
CsvSignal('/Battery/Devices/AlarmFlags/iDM2', read_bool(base_register=1005, bit=29)),
CsvSignal('/Battery/Devices/AlarmFlags/MID2', read_bool(base_register=1005, bit=31)),
CsvSignal('/Battery/Devices/AlarmFlags/HTFS', read_bool(base_register=1005, bit=42)),
CsvSignal('/Battery/Devices/AlarmFlags/DATA', read_bool(base_register=1005, bit=43)),
CsvSignal('/Battery/Devices/AlarmFlags/LMPA', read_bool(base_register=1005, bit=45)),
CsvSignal('/Battery/Devices/AlarmFlags/HEBT', read_bool(base_register=1005, bit=46)),
CsvSignal('/Battery/Devices/AlarmFlags/CURM', read_bool(base_register=1005, bit=48)),
]